Human iPSC-derived Disease Models for Drug Discovery [electronic resource] / edited by Markus H. Kuehn, Wei Zhu.

Colaborador(es): Kuehn, Markus H [editor.] | Zhu, Wei [editor.] | SpringerLink (Online service)Tipo de material: TextoTextoSeries Handbook of Experimental Pharmacology ; 281Editor: Cham : Springer International Publishing : Imprint: Springer, 2023Edición: 1st ed. 2023Descripción: VIII, 332 p. 100 illus., 30 illus. in color. online resourceTipo de contenido: text Tipo de medio: computer Tipo de portador: online resourceISBN: 9783031423499Tema(s): Neurosciences | Regenerative medicine | Stem cells | Neuroscience | Regenerative Medicine and Tissue Engineering | Stem Cell BiologyFormatos físicos adicionales: Printed edition:: Sin título; Printed edition:: Sin título; Printed edition:: Sin títuloClasificación CDD: 612.8 Clasificación LoC:RC321-580Recursos en línea: Libro electrónicoTexto
Contenidos:
Part 1 General considerations -- Human iPS for clinical applications and cellular products -- 3D-printed iPS disease models -- Part 2 CNS iPSC and organoids -- iPS-derived neurons and brain organoids from patients (brain) -- iPS-derived RGCs (eye) -- iPS-derived glia (brain) -- iPSC to model blood-brain barrier endothelial cells -- Part 3 iPSC-derived nociceptive neurons -- IPSC-based peripheral nerve modeling -- Part 4 Non-neuronal specialized cell types -- iPSC-based drug screening of differentiated cardiomyocyte subtypes -- iPSC-based cardiac disease modeling: from cell to tissue -- iPSC-derived corneal endothelial cell -- iPSC-derived trabecular meshwork (eye) -- iPSC for in vitro disease modeling of diabetes.
En: Springer Nature eBookResumen: Since their development a decade ago, human induced pluripotent stem cells (iPSC) have revolutionized the study of human disease, given rise to regenerative medicine technologies, and provided exceptional opportunities for pharmacologic research. These cells provide an essentially unlimited supply of cell types that are difficult to obtain from patients, such as neurons or cardiomyocytes, or are difficult to maintain in primary cell culture. iPSC can be obtained from patients afflicted with a particular disease but, in combination with recently developed gene editing techniques, can also be modified to generate disease models. Moreover, the new techniques of 3 Dimensional printing and materials science facilitate the generation of organoids that can mirror organs under disease conditions. These properties make iPSC powerful tools to study how diseases develop and how they may be treated. In addition, iPSC can also be used to treat conditions in which the target cell population has been lost and such regenerative approaches hold great promise for currently untreatable diseases, including cardiac failure or photoreceptor degenerations.
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Acceso multiusuario

Part 1 General considerations -- Human iPS for clinical applications and cellular products -- 3D-printed iPS disease models -- Part 2 CNS iPSC and organoids -- iPS-derived neurons and brain organoids from patients (brain) -- iPS-derived RGCs (eye) -- iPS-derived glia (brain) -- iPSC to model blood-brain barrier endothelial cells -- Part 3 iPSC-derived nociceptive neurons -- IPSC-based peripheral nerve modeling -- Part 4 Non-neuronal specialized cell types -- iPSC-based drug screening of differentiated cardiomyocyte subtypes -- iPSC-based cardiac disease modeling: from cell to tissue -- iPSC-derived corneal endothelial cell -- iPSC-derived trabecular meshwork (eye) -- iPSC for in vitro disease modeling of diabetes.

Since their development a decade ago, human induced pluripotent stem cells (iPSC) have revolutionized the study of human disease, given rise to regenerative medicine technologies, and provided exceptional opportunities for pharmacologic research. These cells provide an essentially unlimited supply of cell types that are difficult to obtain from patients, such as neurons or cardiomyocytes, or are difficult to maintain in primary cell culture. iPSC can be obtained from patients afflicted with a particular disease but, in combination with recently developed gene editing techniques, can also be modified to generate disease models. Moreover, the new techniques of 3 Dimensional printing and materials science facilitate the generation of organoids that can mirror organs under disease conditions. These properties make iPSC powerful tools to study how diseases develop and how they may be treated. In addition, iPSC can also be used to treat conditions in which the target cell population has been lost and such regenerative approaches hold great promise for currently untreatable diseases, including cardiac failure or photoreceptor degenerations.

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